EL7155 データシートの表示(PDF) - Renesas Electronics
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EL7155 Datasheet PDF : 10 Pages
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EL7155
Applications Information
Product Description
The EL7155 is a high performance 40MHz pin driver. It contains
two analog switches connecting VH to OUTH and VL to OUTL.
Depending on the value of the IN pin, one of the two switches will
be closed and the other switch open. An output enable (OE) is
also supplied, which opens both switches simultaneously.
Due to the topology of the EL7155, VL should always be
connected to a voltage equal to or lower than GND. VH can be
connected to any voltage between VL and the positive supply,
VS+.
The EL7155 is available in the 8 Ld SOIC package. Application
dependent power dissipation should be calculated to ensure that
the maximum junction temperature isn’t violated.
3-state Operation
When the OE pin is low, the output is 3-state (floating.) The
disabled output voltage is the parasitic capacitance’s voltage. It
can be any voltage between VH and VL, depending on the
previous state. At 3-state, the output voltage can be driven to any
voltage between VH and VL. The output voltage can’t be driven
higher than VH or lower than VL since the body diode at the
output stage will turn on.
Supply Voltage Range and Input
Compatibility
The EL7155 is designed for operation on supplies from 5V to 15V
(4.5V to 16.5V maximum). Table 2 on page 7 shows the
specifications for the relationship between the VS+, VH, VL, and
GND pins.
All input pins are compatible with both 3V and 5V CMOS signals.
With a positive supply (VS+) of 5V, the EL7155 is also compatible
with TTL inputs.
Power Supply Bypassing
When using the EL7155, it is very important to use adequate
power supply bypassing. The high switching currents developed
by the EL7155 necessitate the use of a bypass capacitor
between the VS+ and GND pins. It is recommended that a 2.2µF
tantalum capacitor be used in parallel with a 0.1µF
low-inductance ceramic MLC capacitor. These should be placed
as close to the supply pins as possible. It is also recommended
that the VH and VL pins have some level of bypassing, especially
if the EL7155 is driving highly capacitive loads.
Power Dissipation Calculation
When switching at high speeds, or driving heavy loads, the
EL7155 drive capability is limited by the rise in die temperature
brought about by internal power dissipation. For reliable
operation die temperature must be kept below TJMAX (+125°C).
It is necessary to calculate the power dissipation for a given
application prior to selecting the package type.
Power dissipation may be calculated:
PD
=
VS
IS + CINT
VS2
f
+
CL
VO
U
2
T
f
(EQ. 1)
where:
VS is the total power supply to the EL7155 (from VS+ to GND)
VOUT is the swing on the output (VH - VL)
CL is the load capacitance
CINT is the internal load capacitance (100pF max)
IS is the quiescent supply current (3mA max)
f is frequency
Having obtained the application’s power dissipation, a maximum
package thermal coefficient may be determined, to maintain the
internal die temperature below TJMAX:
JA = ---T----J---M-----A----X-P----–D-----T---M-----A----X-----
(EQ. 2)
where:
TJMAX is the maximum junction temperature (+125°C)
TMAX is the maximum operating temperature
PD is the power dissipation calculated above
JA thermal resistance on junction to ambient
JA is 160°C/W for the SO8 package when using a standard
JEDEC JESD51-3 single-layer test board. If TJMAX is greater than
+125°C when calculated using the Equation 2, then one of the
following actions must be taken:
1. Reduce JA the system by designing more heatsinking into
the PCB (as compared to the standard JEDEC JESD51-3).
2. Derate the application either by reducing the switching
frequency, the capacitive load, or the maximum operating
(ambient) temperature (TMAX).
FN7279 Rev 3.00
October 24, 2014
Page 8 of 10
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